The shaded region bounded by $y=3-x^2$, $y=x+x^2$, and $x=-1$ is rotated about the line $x=-1$. The point $P$ is the intersection of $y=3-x^2$ and $y=x+x^2$ in the first quadrant. (i) Find the $x$ coordinate of $P$. (ii) Use the method of cylindrical shells to express the volume of the resulting solid of revolution as an integral. (iii) Evaluate the integral in part (ii). In the diagram, $A$, $B$, $C$ and $D$ are concyclic, and the points $R$, $S$, $T$ are the feet of the perpendiculars from $D$ to $BA$, $AC$ and $BC$ respectively. (i) Show that $\angle DSR = \angle DAR$. (ii) Show that $\angle DST = \pi - \angle DCT$. (iii) Deduce that the points $R$, $S$ and $T$ are collinear. From a pack of nine cards numbered 1, 2, 3, ..., 9, three cards are drawn at random and laid on a table from left to right. (i) What is the probability that the number formed exceeds 400? (ii) What is the probability that the digits are drawn in descending order?

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The shaded region bounded by $y=3-x^2$, $y=x+x^2$, and $x=-1$ is rotated about the line $x=-1$ - HSC - SSCE Mathematics Extension 2 - Question 4 - 2002 - Paper 1

Question 4

The shaded region bounded by $y=3-x^2$, $y=x+x^2$, and $x=-1$ is rotated about the line $x=-1$. The point $P$ is the intersection of $y=3-x^2$ and $y=x+x^2$ in the f... show full transcript

Worked Solution & Example Answer:The shaded region bounded by $y=3-x^2$, $y=x+x^2$, and $x=-1$ is rotated about the line $x=-1$ - HSC - SSCE Mathematics Extension 2 - Question 4 - 2002 - Paper 1

Step 1

Find the $x$ coordinate of $P$.

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Answer

To find the $x$ coordinate of point $P$ , we need to solve the equations of the curves:

$3 - x^2 = x + x^2$ .
Rearranging gives: $x^2 + x - 3 = 0$ .
We can use the quadratic formula: $x = \frac{-b \pm \sqrt{b^2 - 4ac}}{2a}$ where $a=1$ , $b=1$ , and $c=-3$ .
Thus, $x = \frac{-1 \pm \sqrt{1 + 12}}{2} = \frac{-1 \pm \sqrt{13}}{2}$ .
Since we are in the first quadrant, we take the positive solution: $x_P = \frac{-1 + \sqrt{13}}{2}$ .

Step 2

Use the method of cylindrical shells to express the volume of the resulting solid of revolution as an integral.

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Answer

The volume $V$ of the solid of revolution can be calculated using the method of cylindrical shells:

The radius of a typical shell is given by the distance from the axis of rotation to the function, which is $x + 1$ (since we are rotating around $x = -1$ ).
The height of the shell is the difference between the outer function ( $y=3-x^2$ ) and the inner function ( $y=x+x^2$ ).
The formula for the volume of cylindrical shells is: $V = \int_{a}^{b} 2\pi (radius)(height) \,dx$ .
Here, $a$ and $b$ are the points of intersection. Thus, $V = \int_{-1}^{\frac{-1 + \sqrt{13}}{2}} 2\pi (x + 1) ((3 - x^2) - (x + x^2)) \,dx$ .

Step 3

Evaluate the integral in part (ii).

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Answer

To evaluate the integral, we need to simplify the height:

The height is: $3 - x^2 - x - x^2 = 3 - 2x^2 - x$ .
Therefore, the volume integral becomes: $V = 2\pi \int_{-1}^{\frac{-1 + \sqrt{13}}{2}} (x + 1)(3 - 2x^2 - x) \,dx$ .
Expanding this and simplifying the expression will lead to: $V = 2\pi \int_{-1}^{\frac{-1 + \sqrt{13}}{2}} (3x + 3 - 2x^3 - x^2 - 2x) \,dx$ .
Integrate term by term, compute the definite integral, and simplify the result to find the volume.

Step 4

Show that $\angle DSR = \angle DAR$.

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Answer

To show that $\angle DSR = \angle DAR$ , we leverage properties of cyclic quadrilaterals. By the Inscribed Angle Theorem:

$\angle DSR$ subtends arc $DR$ and $\angle DAR$ subtends the same arc $DR$ .
Therefore, by the theorem, $\angle DSR = \angle DAR$ .

Step 5

Show that $\angle DST = \pi - \angle DCT$.

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To show this, we can use similar properties of angles in cyclic quadrilaterals:

Notice that $\angle DST$ and $\angle DCT$ are both subtended by arc $DC$ .
By the properties of angles in circles, we derive: $\angle DST + \angle DCT = \pi$ .
Thus, we can conclude that: $\angle DST = \pi - \angle DCT$ .

Step 6

Deduce that the points $R$, $S$, and $T$ are collinear.

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Using the result from part (ii), if $\angle DST + \angle DCT = \pi$ , it implies that $R$ , $S$ , and $T$ must lie on a straight line. This follows from the fact that the angles add up to a linear pair, indicating collinearity.

Step 7

What is the probability that the number formed exceeds 400?

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Answer

To find the probability that the number exceeds 400, consider that:

The hundreds digit should be 4, 5, 6, 7, 8, or 9, giving us 6 choices.
The number of ways to select the remaining two digits from the other 8 cards: $\binom{8}{2} = 28$
Total successful outcomes = $6 * 28 = 168$ .
Total possible outcomes = $\binom{9}{3} = 84$ .
Therefore, the probability is: $P = \frac{168}{84} = 2$ .

Step 8

What is the probability that the digits are drawn in descending order?

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Answer

To find this probability:

Any selection of 3 digits can be arranged in $3! = 6$ ways.
However, only 1 of those arrangements will be in descending order.
Thus, the probability is: $P = \frac{1}{6}$ .

The shaded region bounded by $y=3-x^2$, $y=x+x^2$, and $x=-1$ is rotated about the line $x=-1$ - HSC - SSCE Mathematics Extension 2 - Question 4 - 2002 - Paper 1

Worked Solution & Example Answer:The shaded region bounded by $y=3-x^2$, $y=x+x^2$, and $x=-1$ is rotated about the line $x=-1$ - HSC - SSCE Mathematics Extension 2 - Question 4 - 2002 - Paper 1

Find the $x$ coordinate of $P$.

Use the method of cylindrical shells to express the volume of the resulting solid of revolution as an integral.

Evaluate the integral in part (ii).

Show that $\angle DSR = \angle DAR$.

Show that $\angle DST = \pi - \angle DCT$.

Deduce that the points $R$, $S$, and $T$ are collinear.

What is the probability that the number formed exceeds 400?

What is the probability that the digits are drawn in descending order?

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